In a hydrogen atom, a transition takes place from n = 3 to n = 2 orbit. Calculate the wavelength of the emitted photon. Will the photon be visible ? To which spectral series will this photon belong? Given `R =1.097 xx 10^(7) m^(-1)`

The first excitation potential of sodium atom is 2.1 V. Calculate the longest wavelength of the emitted photon. Will the photon be visible ? To Which spectral series will this photon belong? Given R = 1.097 xx 10^(7) m^(-1)

In a hydrogen atom, the transition takes place from n = 3 to n = 2 . If Rydberg constant is 1.097xx10^(7)m^(-1) , the wavelength of the emitted radiation is

In hydrogen atom, the transition takes place from n = 3 to n = 2 . If Rydberg's constant is 1.09 xx 10 per metre, the wavelength of the limit emitted is

Calculate the highest frequency of the emitted photon in the Paschen series of spectral lines of the hydrogen atom.

Energy level diagram of a hydrogen atom is shown below : (i)If a transition takes place from n=3 to n=2 orbit, calculate the wavelength of the radiation emitted. Identify the spectral series to which it belongs. (ii)Which transition results in emission of radiation of maximum wavelength ?

If an electron of a hydrogen atom jumps from n = 2 to n=1 then find the wavelength of released photon

Calculate the wavelength (in nanometers) emitted by a photon during a transition from n =6 to n = 4 state in the H -atom.

Find the two longest wavelength ("in" Å) emitted when hydrogen atom make transition and the spectrum lines lie in the visible regain (R = 1.097 xx 10^(7) m^(-1))

In a hydrogen atom , an electron makes a transition from energy level of -1.51 eV to ground level . Calculate the wavelength of the spectral line emitted and identify the series of hydrogen spectrum to which this wavelength belongs.